Your search keyword '"Jones, Kathryn M."' showing total 4 results

1. A broadly distributed predicted helicase/nuclease confers phage resistance via abortive infection.

Author

Sather, Leah M., Zamani, Maryam, Muhammed, Zahed, Kearsley, Jason V.S., Fisher, Gabrielle T., Jones, Kathryn M., and Finan, Turlough M.

Abstract

There is strong selection for the evolution of systems that protect bacterial populations from viral attack. We report a single phage defense protein, Hna, that provides protection against diverse phages in Sinorhizobium meliloti , a nitrogen-fixing alpha-proteobacterium. Homologs of Hna are distributed widely across bacterial lineages, and a homologous protein from Escherichia coli also confers phage defense. Hna contains superfamily II helicase motifs at its N terminus and a nuclease motif at its C terminus, with mutagenesis of these motifs inactivating viral defense. Hna variably impacts phage DNA replication but consistently triggers an abortive infection response in which infected cells carrying the system die but do not release phage progeny. A similar host cell response is triggered in cells containing Hna upon expression of a phage-encoded single-stranded DNA binding protein (SSB), independent of phage infection. Thus, we conclude that Hna limits phage spread by initiating abortive infection in response to a phage protein. [Display omitted] • The helicase/nuclease Hna confers defense against phages in Sinorhizobium meliloti • A homologous protein from Escherichia coli also has antiphage activity • Hna prevents phage propagation through an abortive infection mechanism • A phage single-stranded DNA binding protein triggers an Hna anti-host response Microorganisms have evolved a variety of systems to combat viral infection. Sather et al. describe a bacteriophage defense system ("Hna") consisting of a single predicted helicase/nuclease that confers protection by abortive infection. Homologs of Hna are present in a wide array of bacteria, including many medically or agriculturally relevant species. [ABSTRACT FROM AUTHOR]

Published

2023

2. The genome, proteome and phylogenetic analysis of Sinorhizobium meliloti phage ΦM12, the founder of a new group of T4-superfamily phages.

Author

Brewer, Tess E., Elizabeth Stroupe, M., and Jones, Kathryn M.

Subjects

*BACTERIAL genomes, *BACTERIA phylogeny, *NITROGEN-fixing bacteria, *BACTERIOPHAGES, *RHIZOBIUM, *RIBONUCLEOSIDE diphosphate reductase

Abstract

Abstract: Phage ΦM12 is an important transducing phage of the nitrogen-fixing rhizobial bacterium Sinorhizobium meliloti. Here we report the genome, phylogenetic analysis, and proteome of ΦM12, the first report of the genome and proteome of a rhizobium-infecting T4-superfamily phage. The structural genes of ΦM12 are most similar to T4-superfamily phages of cyanobacteria. ΦM12 is the first reported T4-superfamily phage to lack genes encoding class I ribonucleotide reductase (RNR) and exonuclease dexA, and to possess a class II coenzyme B12-dependent RNR. ΦM12’s novel collection of genes establishes it as the founder of a new group of T4-superfamily phages, fusing features of cyanophages and phages of enteric bacteria. [Copyright &y& Elsevier]

Published

2014

3. Structure, proteome and genome of Sinorhizobium meliloti phage ΦM5: A virus with LUZ24-like morphology and a highly mosaic genome.

Author

Johnson, Matthew C., Sena-Velez, Marta, Washburn, Brian K., Platt, Georgia N., Lu, Stephen, Brewer, Tess E., Lynn, Jason S., Stroupe, M. Elizabeth, and Jones, Kathryn M.

Subjects

*BACTERIOPHAGES, *PROTEOMICS, *GENOMICS, *NITROGEN-fixing bacteria, *ELECTRON microscopy

Abstract

Bacteriophages of nitrogen-fixing rhizobial bacteria are revealing a wealth of novel structures, diverse enzyme combinations and genomic features. Here we report the cryo-EM structure of the phage capsid at 4.9–5.7 Å-resolution, the phage particle proteome, and the genome of the Sinorhizobium meliloti -infecting Podovirus ΦM5. This is the first structure of a phage with a capsid and capsid-associated structural proteins related to those of the LUZ24-like viruses that infect Pseudomonas aeruginosa . Like many other Podoviruses, ΦM5 is a T = 7 icosahedron with a smooth capsid and short, relatively featureless tail. Nonetheless, this group is phylogenetically quite distinct from Podoviruses of the well-characterized T7, P22, and epsilon 15 supergroups. Structurally, a distinct bridge of density that appears unique to ΦM5 reaches down the body of the coat protein to the extended loop that interacts with the next monomer in a hexamer, perhaps stabilizing the mature capsid. Further, the predicted tail fibers of ΦM5 are quite different from those of enteric bacteria phages, but have domains in common with other rhizophages. Genomically, ΦM5 is highly mosaic. The ΦM5 genome is 44,005 bp with 357 bp direct terminal repeats (DTRs) and 58 unique ORFs. Surprisingly, the capsid structural module, the tail module, the DNA-packaging terminase, the DNA replication module and the integrase each appear to be from a different lineage. One of the most unusual features of ΦM5 is its terminase whose large subunit is quite different from previously-described short-DTR-generating packaging machines and does not fit into any of the established phylogenetic groups. [ABSTRACT FROM AUTHOR]

Published

2017

4. The structure of Sinorhizobium meliloti phage ΦM12, which has a novel T=19l triangulation number and is the founder of a new group of T4-superfamily phages.

Author

Stroupe, M. Elizabeth, Brewer, Tess E., Sousa, Duncan R., and Jones, Kathryn M.

Subjects

*BACTERIOPHAGES, *TRIANGULATION, *CAPSIDS, *VIRAL genomes, *VIRAL proteins, *ICOSAHEDRA

Abstract

Abstract: ΦM12 is the first example of a T=19l geometry capsid, encapsulating the recently sequenced genome. Here, we present structures determined by cryo-EM of full and empty capsids. The structure reveals the pattern for assembly of 1140 HK97-like capsid proteins, pointing to interactions at the pseudo 3-fold symmetry axes that hold together the asymmetric unit. The particular smooth surface of the capsid, along with a lack of accessory coat proteins encoded by the genome, suggest that this interface is the primary mechanism for capsid assembly. Two-dimensional averages of the tail, including the neck and baseplate, reveal that ΦM12 has a relatively narrow neck that attaches the tail to the capsid, as well as a three-layer baseplate. When free from DNA, the icosahedral edges expand by about 5nm, while the vertices stay at the same position, forming a similarly smooth, but bowed, T=19l icosahedral capsid. [Copyright &y& Elsevier]

Published

2014